Temperature and oxygen supply shape the demersal community in a tropical Oxygen Minimum Zone

• Published in: Environmental biology of fishes Vol. 105; no. 10; pp. 1317 - 1333
• Main Authors: Clarke, Tayler M., Frölicher, Thomas, Reygondeau, Gabriel, Villalobos-Rojas, Fresia, Wabnitz, Colette C. C., Wehrtmann, Ingo S., Cheung, William W. L.
• Format: Journal Article
• Language: English
• Published: Dordrecht Springer Netherlands 01.10.2022; Springer Nature B.V
• Subjects: Adaptation; Animal Systematics/Taxonomy/Biogeography; Biomedical and Life Sciences; Climate change; Community composition; Deoxygenation; El Nino; El Nino phenomena; Environment; Environmental conditions; Environmental effects; Freshwater & Marine Ecology; Geographical distribution; Hypoxia; La Nina; Life Sciences; Marine animals; Marine ecosystems; Marine fauna; Nature Conservation; Oxygen; Oxygen demand; Oxygen requirement; Partial pressure; Perturbation; Physiological effects; Seawater; Southern Oscillation; Species; Species diversity; Survival; Temperature; Vulnerability; Water temperature; Zoology; ENSO; Eastern Tropical Pacific; Oxygen partial pressure; Hypoxia; Shrimp fisheries; Demersal fish communities; Costa Rica
• ISSN: 0378-1909; 1573-5133
• DOI: 10.1007/s10641-022-01256-2

The organisms that inhabit Oxygen Minimum Zones (OMZ) have specialized adaptations that allow them to survive within a very narrow range of environmental conditions. Consequently, even small environmental perturbations can result in local species distribution shifts that alter ecosystem trophodynamics. Here, we examined the effect of changing sea water temperatures and oxygen levels on the physiological performance and metabolic traits of the species forming marine demersal communities along the OMZ margins in the Costa Rican Pacific. The strong temperature and oxygen gradients along this OMZ margin provide a “natural experiment” to explore the effects of warming and hypoxia on marine demersal communities. We identified two distinct marine fauna communities separated by an environmental oxygen partial pressure threshold of 0.003–0.009 atm. The community inhabiting cooler waters with less oxygen was comprised of species with very low oxygen demands, while the second community inhabiting warmer waters with more oxygen was comprised by a higher diversity of species with higher oxygen demands. We also compared the community composition across different El Niño Southern Oscillation phases. During “neutral” and El Niño conditions, with relatively warmer temperatures and higher oxygen levels, species’ average oxygen demand was higher, and species stayed at greater depths than during the cooler, low oxygen, La Niña phases. Our findings suggest that the effects of environmental temperature and oxygen levels on the structure of demersal communities within OMZs can be predicted by understanding species’ oxygen demand. This study highlights the vulnerability of demersal ecosystem structures surrounding the Costa Rican OMZ to deoxygenation and warming under climate change.